Genes within genes: multiple LAGLIDADG homing endonucleases target the ribosomal protein S3 gene encoded within an rnl group I intron of Ophiostoma and related taxa.

In some ascomycete fungi, ribosomal protein S3 (Rps3) is encoded within a group I intron (mL2449) that is inserted in the U11 region of the mitochondrial large subunit rDNA (rnl) gene. Previous characterization of the mL2449 intron in strains of Ophiostoma novo-ulmi subspecies americana (Dutch Elm Disease) revealed a complex genes-within-genes arrangement whereby a LAGLIDADG homing endonuclease gene (HEG) is inserted into the RPS3 gene near the 3' terminus, creating a hybrid Rps3-LAGLIDADG fusion protein. Here, we examined 119 additional strains of Ophiostoma and related taxa representing 85 different species by a polymerase chain reaction- based survey and detected both short (approximately 1.6 kb) and long (>2.2 kb) versions of the mL2449 intron in 88 and 31 strains, respectively. Among the long versions encountered, 21 were sequenced, revealing the presence of either intact or degenerated HEG-coding regions inserted within the RPS3 gene. Surprisingly, we identified two new HEG insertion sites in RPS3; one near the original C-terminal insertion site and one near the N-terminus of RPS3. In all instances, the HEGs are fused in-frame with the RPS3-coding sequences to create fusion proteins. However, comparative sequence analysis showed that upon insertion, the HEGs displaced a portion of the RPS3-coding region. Remarkably, the displaced RPS3-coding segments are duplicated and fused in-frame to the 3' end of RPS3, restoring a full-length RPS3 gene. We cloned and expressed the LAGLIDADG portion of two Rps3-HEG fusions, and showed that I-OnuI and I-LtrI generate 4 nucleotide (nt), 3' overhangs, and cleave at or 1 nt upstream of the HEG insertion site, respectively. Collectively, our data indicate that RPS3 genes are a refuge for distinct types of LAGLIDADG HEGs that are defined by the presence of duplicated segments of the host gene that restore the RPS3 gene, thus minimizing the impact of the HEG insertion on Rps3 function.

Selfish DNA: the best defense is a good offense.

The recent discovery of novel biochemical activities of intron-encoded endonucleases emphasizes the selfish nature of mobile genetic elements.

Related homing endonucleases I-BmoI and I-TevI use different strategies to cleave homologous recognition sites.

A typical homing endonuclease initiates mobility of its group I intron by recognizing DNA both upstream and downstream of the intron insertion site of intronless alleles, preventing the endonuclease from binding and cleaving its own intron-containing allele. Here, we describe a GIY-YIG family homing endonuclease, I-BmoI, that possesses an unusual recognition sequence, encompassing 1 base pair upstream but 38 base pairs downstream of the intron insertion site. I-BmoI binds intron-containing and intronless substrates with equal affinity but can nevertheless discriminate between the two for cleavage. I-BmoI is encoded by a group I intron that interrupts the thymidylate synthase (TS) gene (thyA) of Bacillus mojavensis s87-18. This intron resembles one inserted 21 nucleotides further downstream in a homologous TS gene (td) of Escherichia coli phage T4. I-TevI, the T4 td intron-encoded GIY-YIG endonuclease, is very similar to I-BmoI, but each endonuclease gene is inserted within a different position of its respective intron. Remarkably, I-TevI and I-BmoI bind a homologous stretch of TS-encoding DNA and cleave their intronless substrates in very similar positions. Our results suggest that each endonuclease has independently evolved the ability to distinguish intron-containing from intronless alleles while maintaining the same conserved recognition sequence centered on DNA-encoding active site residues of TS.

Gene duplications in evolution of archaeal family B DNA polymerases.

All archaeal DNA-dependent DNA polymerases sequenced to date are homologous to family B DNA polymerases from eukaryotes and eubacteria. Presently, representatives of the euryarchaeote division of archaea appear to have a single family B DNA polymerase, whereas two crenarchaeotes, Pyrodictium occultum and Sulfolobus solfataricus, each possess two family B DNA polymerases. We have found the gene for yet a third family B DNA polymerase, designated B3, in the crenarchaeote S. solfataricus P2. The encoded protein is highly divergent at the amino acid level from the previously characterized family B polymerases in S. solfataricus P2 and contains a number of nonconserved amino acid substitutions in catalytic domains. We have cloned and sequenced the ortholog of this gene from the closely related Sulfolobus shibatae. It is also highly divergent from other archaeal family B DNA polymerases and, surprisingly, from the S. solfataricus B3 ortholog. Phylogenetic analysis using all available archaeal family B DNA polymerases suggests that the S. solfataricus P2 B3 and S. shibatae B3 paralogs are related to one of the two DNA polymerases of P. occultum. These sequences are members of a group which includes all euryarchaeote family B homologs, while the remaining crenarchaeote sequences form another distinct group. Archaeal family B DNA polymerases together constitute a monophyletic subfamily whose evolution has been characterized by a number of gene duplication events.

Evidence of independent gene duplications during the evolution of archaeal and eukaryotic family B DNA polymerases.

Eukaryotes and archaea both possess multiple genes coding for family B DNA polymerases. In animals and fungi, three family B DNA polymerases, alpha, delta, and epsilon, are responsible for replication of nuclear DNA. We used a PCR-based approach to amplify and sequence phylogenetically conserved regions of these three DNA polymerases from Giardia intestinalis and Trichomonas vaginalis, representatives of early-diverging eukaryotic lineages. Phylogenetic analysis of eukaryotic and archaeal paralogs suggests that the gene duplications that gave rise to the three replicative paralogs occurred before the divergence of the earliest eukaryotic lineages, and that all eukaryotes are likely to possess these paralogs. One eukaryotic paralog, epsilon, consistently branches within archaeal sequences to the exclusion of other eukaryotic paralogs, suggesting that an epsilon-like family B DNA polymerase was ancestral to both archaea and eukaryotes. Because crenarchaeote and euryarchaeote paralogs do not form monophyletic groups in phylogenetic analysis, it is possible that archaeal family B paralogs themselves evolved by a series of gene duplications independent of the gene duplications that gave rise to eukaryotic paralogs.